(function(f){if(typeof exports==="object"&&typeof module!=="undefined"){module.exports=f()}else if(typeof define==="function"&&define.amd){define([],f)}else{var g;if(typeof window!=="undefined"){g=window}else if(typeof global!=="undefined"){g=global}else if(typeof self!=="undefined"){g=self}else{g=this}g.poly2tri = f()}})(function(){var define,module,exports;return (function e(t,n,r){function s(o,u){if(!n[o]){if(!t[o]){var a=typeof require=="function"&&require;if(!u&&a)return a(o,!0);if(i)return i(o,!0);var f=new Error("Cannot find module '"+o+"'");throw f.code="MODULE_NOT_FOUND",f}var l=n[o]={exports:{}};t[o][0].call(l.exports,function(e){var n=t[o][1][e];return s(n?n:e)},l,l.exports,e,t,n,r)}return n[o].exports}var i=typeof require=="function"&&require;for(var o=0;o<r.length;o++)s(r[o]);return s})({1:[function(require,module,exports){
module.exports={"version": "1.5.0"}
},{}],2:[function(require,module,exports){
/*
 * Poly2Tri Copyright (c) 2009-2014, Poly2Tri Contributors
 * http://code.google.com/p/poly2tri/
 *
 * poly2tri.js (JavaScript port) (c) 2009-2014, Poly2Tri Contributors
 * https://github.com/r3mi/poly2tri.js
 *
 * All rights reserved.
 *
 * Distributed under the 3-clause BSD License, see LICENSE.txt
 */

/* jshint maxcomplexity:11 */

"use strict";


/*
 * Note
 * ====
 * the structure of this JavaScript version of poly2tri intentionally follows
 * as closely as possible the structure of the reference C++ version, to make it
 * easier to keep the 2 versions in sync.
 */


// -------------------------------------------------------------------------Node

/**
 * Advancing front node
 * @constructor
 * @private
 * @struct
 * @param {!XY} p - Point
 * @param {Triangle=} t triangle (optional)
 */
var Node = function(p, t) {
    /** @type {XY} */
    this.point = p;

    /** @type {Triangle|null} */
    this.triangle = t || null;

    /** @type {Node|null} */
    this.next = null;
    /** @type {Node|null} */
    this.prev = null;

    /** @type {number} */
    this.value = p.x;
};

// ---------------------------------------------------------------AdvancingFront
/**
 * @constructor
 * @private
 * @struct
 * @param {Node} head
 * @param {Node} tail
 */
var AdvancingFront = function(head, tail) {
    /** @type {Node} */
    this.head_ = head;
    /** @type {Node} */
    this.tail_ = tail;
    /** @type {Node} */
    this.search_node_ = head;
};

/** @return {Node} */
AdvancingFront.prototype.head = function() {
    return this.head_;
};

/** @param {Node} node */
AdvancingFront.prototype.setHead = function(node) {
    this.head_ = node;
};

/** @return {Node} */
AdvancingFront.prototype.tail = function() {
    return this.tail_;
};

/** @param {Node} node */
AdvancingFront.prototype.setTail = function(node) {
    this.tail_ = node;
};

/** @return {Node} */
AdvancingFront.prototype.search = function() {
    return this.search_node_;
};

/** @param {Node} node */
AdvancingFront.prototype.setSearch = function(node) {
    this.search_node_ = node;
};

/** @return {Node} */
AdvancingFront.prototype.findSearchNode = function(/*x*/) {
    // TODO: implement BST index
    return this.search_node_;
};

/**
 * @param {number} x value
 * @return {Node}
 */
AdvancingFront.prototype.locateNode = function(x) {
    var node = this.search_node_;

    /* jshint boss:true */
    if (x < node.value) {
        while (node = node.prev) {
            if (x >= node.value) {
                this.search_node_ = node;
                return node;
            }
        }
    } else {
        while (node = node.next) {
            if (x < node.value) {
                this.search_node_ = node.prev;
                return node.prev;
            }
        }
    }
    return null;
};

/**
 * @param {!XY} point - Point
 * @return {Node}
 */
AdvancingFront.prototype.locatePoint = function(point) {
    var px = point.x;
    var node = this.findSearchNode(px);
    var nx = node.point.x;

    if (px === nx) {
        // Here we are comparing point references, not values
        if (point !== node.point) {
            // We might have two nodes with same x value for a short time
            if (point === node.prev.point) {
                node = node.prev;
            } else if (point === node.next.point) {
                node = node.next;
            } else {
                throw new Error('poly2tri Invalid AdvancingFront.locatePoint() call');
            }
        }
    } else if (px < nx) {
        /* jshint boss:true */
        while (node = node.prev) {
            if (point === node.point) {
                break;
            }
        }
    } else {
        while (node = node.next) {
            if (point === node.point) {
                break;
            }
        }
    }

    if (node) {
        this.search_node_ = node;
    }
    return node;
};


// ----------------------------------------------------------------------Exports

module.exports = AdvancingFront;
module.exports.Node = Node;


},{}],3:[function(require,module,exports){
/*
 * Poly2Tri Copyright (c) 2009-2014, Poly2Tri Contributors
 * http://code.google.com/p/poly2tri/
 *
 * poly2tri.js (JavaScript port) (c) 2009-2014, Poly2Tri Contributors
 * https://github.com/r3mi/poly2tri.js
 *
 * All rights reserved.
 *
 * Distributed under the 3-clause BSD License, see LICENSE.txt
 */

"use strict";

/*
 * Function added in the JavaScript version (was not present in the c++ version)
 */

/**
 * assert and throw an exception.
 *
 * @private
 * @param {boolean} condition   the condition which is asserted
 * @param {string} message      the message which is display is condition is falsy
 */
function assert(condition, message) {
    if (!condition) {
        throw new Error(message || "Assert Failed");
    }
}
module.exports = assert;



},{}],4:[function(require,module,exports){
/*
 * Poly2Tri Copyright (c) 2009-2014, Poly2Tri Contributors
 * http://code.google.com/p/poly2tri/
 *
 * poly2tri.js (JavaScript port) (c) 2009-2014, Poly2Tri Contributors
 * https://github.com/r3mi/poly2tri.js
 *
 * All rights reserved.
 *
 * Distributed under the 3-clause BSD License, see LICENSE.txt
 */

"use strict";


/*
 * Note
 * ====
 * the structure of this JavaScript version of poly2tri intentionally follows
 * as closely as possible the structure of the reference C++ version, to make it
 * easier to keep the 2 versions in sync.
 */

var xy = require('./xy');

// ------------------------------------------------------------------------Point
/**
 * Construct a point
 * @example
 *      var point = new poly2tri.Point(150, 150);
 * @public
 * @constructor
 * @struct
 * @param {number=} x    coordinate (0 if undefined)
 * @param {number=} y    coordinate (0 if undefined)
 */
var Point = function(x, y) {
    /**
     * @type {number}
     * @expose
     */
    this.x = +x || 0;
    /**
     * @type {number}
     * @expose
     */
    this.y = +y || 0;

    // All extra fields added to Point are prefixed with _p2t_
    // to avoid collisions if custom Point class is used.

    /**
     * The edges this point constitutes an upper ending point
     * @private
     * @type {Array.<Edge>}
     */
    this._p2t_edge_list = null;
};

/**
 * For pretty printing
 * @example
 *      "p=" + new poly2tri.Point(5,42)
 *      // → "p=(5;42)"
 * @returns {string} <code>"(x;y)"</code>
 */
Point.prototype.toString = function() {
    return xy.toStringBase(this);
};

/**
 * JSON output, only coordinates
 * @example
 *      JSON.stringify(new poly2tri.Point(1,2))
 *      // → '{"x":1,"y":2}'
 */
Point.prototype.toJSON = function() {
    return { x: this.x, y: this.y };
};

/**
 * Creates a copy of this Point object.
 * @return {Point} new cloned point
 */
Point.prototype.clone = function() {
    return new Point(this.x, this.y);
};

/**
 * Set this Point instance to the origo. <code>(0; 0)</code>
 * @return {Point} this (for chaining)
 */
Point.prototype.set_zero = function() {
    this.x = 0.0;
    this.y = 0.0;
    return this; // for chaining
};

/**
 * Set the coordinates of this instance.
 * @param {number} x   coordinate
 * @param {number} y   coordinate
 * @return {Point} this (for chaining)
 */
Point.prototype.set = function(x, y) {
    this.x = +x || 0;
    this.y = +y || 0;
    return this; // for chaining
};

/**
 * Negate this Point instance. (component-wise)
 * @return {Point} this (for chaining)
 */
Point.prototype.negate = function() {
    this.x = -this.x;
    this.y = -this.y;
    return this; // for chaining
};

/**
 * Add another Point object to this instance. (component-wise)
 * @param {!Point} n - Point object.
 * @return {Point} this (for chaining)
 */
Point.prototype.add = function(n) {
    this.x += n.x;
    this.y += n.y;
    return this; // for chaining
};

/**
 * Subtract this Point instance with another point given. (component-wise)
 * @param {!Point} n - Point object.
 * @return {Point} this (for chaining)
 */
Point.prototype.sub = function(n) {
    this.x -= n.x;
    this.y -= n.y;
    return this; // for chaining
};

/**
 * Multiply this Point instance by a scalar. (component-wise)
 * @param {number} s   scalar.
 * @return {Point} this (for chaining)
 */
Point.prototype.mul = function(s) {
    this.x *= s;
    this.y *= s;
    return this; // for chaining
};

/**
 * Return the distance of this Point instance from the origo.
 * @return {number} distance
 */
Point.prototype.length = function() {
    return Math.sqrt(this.x * this.x + this.y * this.y);
};

/**
 * Normalize this Point instance (as a vector).
 * @return {number} The original distance of this instance from the origo.
 */
Point.prototype.normalize = function() {
    var len = this.length();
    this.x /= len;
    this.y /= len;
    return len;
};

/**
 * Test this Point object with another for equality.
 * @param {!XY} p - any "Point like" object with {x,y}
 * @return {boolean} <code>true</code> if same x and y coordinates, <code>false</code> otherwise.
 */
Point.prototype.equals = function(p) {
    return this.x === p.x && this.y === p.y;
};


// -----------------------------------------------------Point ("static" methods)

/**
 * Negate a point component-wise and return the result as a new Point object.
 * @param {!XY} p - any "Point like" object with {x,y}
 * @return {Point} the resulting Point object.
 */
Point.negate = function(p) {
    return new Point(-p.x, -p.y);
};

/**
 * Add two points component-wise and return the result as a new Point object.
 * @param {!XY} a - any "Point like" object with {x,y}
 * @param {!XY} b - any "Point like" object with {x,y}
 * @return {Point} the resulting Point object.
 */
Point.add = function(a, b) {
    return new Point(a.x + b.x, a.y + b.y);
};

/**
 * Subtract two points component-wise and return the result as a new Point object.
 * @param {!XY} a - any "Point like" object with {x,y}
 * @param {!XY} b - any "Point like" object with {x,y}
 * @return {Point} the resulting Point object.
 */
Point.sub = function(a, b) {
    return new Point(a.x - b.x, a.y - b.y);
};

/**
 * Multiply a point by a scalar and return the result as a new Point object.
 * @param {number} s - the scalar
 * @param {!XY} p - any "Point like" object with {x,y}
 * @return {Point} the resulting Point object.
 */
Point.mul = function(s, p) {
    return new Point(s * p.x, s * p.y);
};

/**
 * Perform the cross product on either two points (this produces a scalar)
 * or a point and a scalar (this produces a point).
 * This function requires two parameters, either may be a Point object or a
 * number.
 * @param  {XY|number} a - Point object or scalar.
 * @param  {XY|number} b - Point object or scalar.
 * @return {Point|number} a Point object or a number, depending on the parameters.
 */
Point.cross = function(a, b) {
    if (typeof(a) === 'number') {
        if (typeof(b) === 'number') {
            return a * b;
        } else {
            return new Point(-a * b.y, a * b.x);
        }
    } else {
        if (typeof(b) === 'number') {
            return new Point(b * a.y, -b * a.x);
        } else {
            return a.x * b.y - a.y * b.x;
        }
    }
};


// -----------------------------------------------------------------"Point-Like"
/*
 * The following functions operate on "Point" or any "Point like" object
 * with {x,y} (duck typing).
 */

Point.toString = xy.toString;
Point.compare = xy.compare;
Point.cmp = xy.compare; // backward compatibility
Point.equals = xy.equals;

/**
 * Peform the dot product on two vectors.
 * @public
 * @param {!XY} a - any "Point like" object with {x,y}
 * @param {!XY} b - any "Point like" object with {x,y}
 * @return {number} The dot product
 */
Point.dot = function(a, b) {
    return a.x * b.x + a.y * b.y;
};


// ---------------------------------------------------------Exports (public API)


module.exports = Point;

},{"./xy":11}],5:[function(require,module,exports){
/*
 * Poly2Tri Copyright (c) 2009-2014, Poly2Tri Contributors
 * http://code.google.com/p/poly2tri/
 *
 * poly2tri.js (JavaScript port) (c) 2009-2014, Poly2Tri Contributors
 * https://github.com/r3mi/poly2tri.js
 *
 * All rights reserved.
 *
 * Distributed under the 3-clause BSD License, see LICENSE.txt
 */

"use strict";

/*
 * Class added in the JavaScript version (was not present in the c++ version)
 */

var xy = require('./xy');

/**
 * Custom exception class to indicate invalid Point values
 * @constructor
 * @public
 * @extends Error
 * @struct
 * @param {string=} message - error message
 * @param {Array.<XY>=} points - invalid points
 */
var PointError = function(message, points) {
    this.name = "PointError";
    /**
     * Invalid points
     * @public
     * @type {Array.<XY>}
     */
    this.points = points = points || [];
    /**
     * Error message
     * @public
     * @type {string}
     */
    this.message = message || "Invalid Points!";
    for (var i = 0; i < points.length; i++) {
        this.message += " " + xy.toString(points[i]);
    }
};
PointError.prototype = new Error();
PointError.prototype.constructor = PointError;


module.exports = PointError;

},{"./xy":11}],6:[function(require,module,exports){
(function (global){
/*
 * Poly2Tri Copyright (c) 2009-2014, Poly2Tri Contributors
 * http://code.google.com/p/poly2tri/
 *
 * poly2tri.js (JavaScript port) (c) 2009-2014, Poly2Tri Contributors
 * https://github.com/r3mi/poly2tri.js
 *
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without modification,
 * are permitted provided that the following conditions are met:
 *
 * * Redistributions of source code must retain the above copyright notice,
 *   this list of conditions and the following disclaimer.
 * * Redistributions in binary form must reproduce the above copyright notice,
 *   this list of conditions and the following disclaimer in the documentation
 *   and/or other materials provided with the distribution.
 * * Neither the name of Poly2Tri nor the names of its contributors may be
 *   used to endorse or promote products derived from this software without specific
 *   prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR
 * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
 * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
 * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
 * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
 * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
 * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
 * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 */

"use strict";

/**
 * Public API for poly2tri.js
 * @module poly2tri
 */


/**
 * If you are not using a module system (e.g. CommonJS, RequireJS), you can access this library
 * as a global variable <code>poly2tri</code> i.e. <code>window.poly2tri</code> in a browser.
 * @name poly2tri
 * @global
 * @public
 * @type {module:poly2tri}
 */
var previousPoly2tri = global.poly2tri;
/**
 * For Browser + &lt;script&gt; :
 * reverts the {@linkcode poly2tri} global object to its previous value,
 * and returns a reference to the instance called.
 *
 * @example
 *              var p = poly2tri.noConflict();
 * @public
 * @return {module:poly2tri} instance called
 */
// (this feature is not automatically provided by browserify).
exports.noConflict = function() {
    global.poly2tri = previousPoly2tri;
    return exports;
};

/**
 * poly2tri library version
 * @public
 * @const {string}
 */
exports.VERSION = require('../dist/version.json').version;

/**
 * Exports the {@linkcode PointError} class.
 * @public
 * @typedef {PointError} module:poly2tri.PointError
 * @function
 */
exports.PointError = require('./pointerror');
/**
 * Exports the {@linkcode Point} class.
 * @public
 * @typedef {Point} module:poly2tri.Point
 * @function
 */
exports.Point = require('./point');
/**
 * Exports the {@linkcode Triangle} class.
 * @public
 * @typedef {Triangle} module:poly2tri.Triangle
 * @function
 */
exports.Triangle = require('./triangle');
/**
 * Exports the {@linkcode SweepContext} class.
 * @public
 * @typedef {SweepContext} module:poly2tri.SweepContext
 * @function
 */
exports.SweepContext = require('./sweepcontext');


// Backward compatibility
var sweep = require('./sweep');
/**
 * @function
 * @deprecated use {@linkcode SweepContext#triangulate} instead
 */
exports.triangulate = sweep.triangulate;
/**
 * @deprecated use {@linkcode SweepContext#triangulate} instead
 * @property {function} Triangulate - use {@linkcode SweepContext#triangulate} instead
 */
exports.sweep = {Triangulate: sweep.triangulate};

}).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {})
},{"../dist/version.json":1,"./point":4,"./pointerror":5,"./sweep":7,"./sweepcontext":8,"./triangle":9}],7:[function(require,module,exports){
/*
 * Poly2Tri Copyright (c) 2009-2014, Poly2Tri Contributors
 * http://code.google.com/p/poly2tri/
 *
 * poly2tri.js (JavaScript port) (c) 2009-2014, Poly2Tri Contributors
 * https://github.com/r3mi/poly2tri.js
 *
 * All rights reserved.
 *
 * Distributed under the 3-clause BSD License, see LICENSE.txt
 */

/* jshint latedef:nofunc, maxcomplexity:9 */

"use strict";

/**
 * This 'Sweep' module is present in order to keep this JavaScript version
 * as close as possible to the reference C++ version, even though almost all
 * functions could be declared as methods on the {@linkcode module:sweepcontext~SweepContext} object.
 * @module
 * @private
 */

/*
 * Note
 * ====
 * the structure of this JavaScript version of poly2tri intentionally follows
 * as closely as possible the structure of the reference C++ version, to make it
 * easier to keep the 2 versions in sync.
 */

var assert = require('./assert');
var PointError = require('./pointerror');
var Triangle = require('./triangle');
var Node = require('./advancingfront').Node;


// ------------------------------------------------------------------------utils

var utils = require('./utils');

/** @const */
var EPSILON = utils.EPSILON;

/** @const */
var Orientation = utils.Orientation;
/** @const */
var orient2d = utils.orient2d;
/** @const */
var inScanArea = utils.inScanArea;
/** @const */
var isAngleObtuse = utils.isAngleObtuse;


// ------------------------------------------------------------------------Sweep

/**
 * Triangulate the polygon with holes and Steiner points.
 * Do this AFTER you've added the polyline, holes, and Steiner points
 * @private
 * @param {!SweepContext} tcx - SweepContext object
 */
function triangulate(tcx) {
    tcx.initTriangulation();
    tcx.createAdvancingFront();
    // Sweep points; build mesh
    sweepPoints(tcx);
    // Clean up
    finalizationPolygon(tcx);
}

/**
 * Start sweeping the Y-sorted point set from bottom to top
 * @param {!SweepContext} tcx - SweepContext object
 */
function sweepPoints(tcx) {
    var i, len = tcx.pointCount();
    for (i = 1; i < len; ++i) {
        var point = tcx.getPoint(i);
        var node = pointEvent(tcx, point);
        var edges = point._p2t_edge_list;
        for (var j = 0; edges && j < edges.length; ++j) {
            edgeEventByEdge(tcx, edges[j], node);
        }
    }
}

/**
 * @param {!SweepContext} tcx - SweepContext object
 */
function finalizationPolygon(tcx) {
    // Get an Internal triangle to start with
    var t = tcx.front().head().next.triangle;
    var p = tcx.front().head().next.point;
    while (!t.getConstrainedEdgeCW(p)) {
        t = t.neighborCCW(p);
    }

    // Collect interior triangles constrained by edges
    tcx.meshClean(t);
}

/**
 * Find closes node to the left of the new point and
 * create a new triangle. If needed new holes and basins
 * will be filled to.
 * @param {!SweepContext} tcx - SweepContext object
 * @param {!XY} point   Point
 */
function pointEvent(tcx, point) {
    var node = tcx.locateNode(point);
    var new_node = newFrontTriangle(tcx, point, node);

    // Only need to check +epsilon since point never have smaller
    // x value than node due to how we fetch nodes from the front
    if (point.x <= node.point.x + (EPSILON)) {
        fill(tcx, node);
    }

    //tcx.AddNode(new_node);

    fillAdvancingFront(tcx, new_node);
    return new_node;
}

function edgeEventByEdge(tcx, edge, node) {
    tcx.edge_event.constrained_edge = edge;
    tcx.edge_event.right = (edge.p.x > edge.q.x);

    if (isEdgeSideOfTriangle(node.triangle, edge.p, edge.q)) {
        return;
    }

    // For now we will do all needed filling
    // TODO: integrate with flip process might give some better performance
    //       but for now this avoid the issue with cases that needs both flips and fills
    fillEdgeEvent(tcx, edge, node);
    edgeEventByPoints(tcx, edge.p, edge.q, node.triangle, edge.q);
}

function edgeEventByPoints(tcx, ep, eq, triangle, point) {
    if (isEdgeSideOfTriangle(triangle, ep, eq)) {
        return;
    }

    var p1 = triangle.pointCCW(point);
    var o1 = orient2d(eq, p1, ep);
    if (o1 === Orientation.COLLINEAR) {
        // TODO integrate here changes from C++ version
        // (C++ repo revision 09880a869095 dated March 8, 2011)
        throw new PointError('poly2tri EdgeEvent: Collinear not supported!', [eq, p1, ep]);
    }

    var p2 = triangle.pointCW(point);
    var o2 = orient2d(eq, p2, ep);
    if (o2 === Orientation.COLLINEAR) {
        // TODO integrate here changes from C++ version
        // (C++ repo revision 09880a869095 dated March 8, 2011)
        throw new PointError('poly2tri EdgeEvent: Collinear not supported!', [eq, p2, ep]);
    }

    if (o1 === o2) {
        // Need to decide if we are rotating CW or CCW to get to a triangle
        // that will cross edge
        if (o1 === Orientation.CW) {
            triangle = triangle.neighborCCW(point);
        } else {
            triangle = triangle.neighborCW(point);
        }
        edgeEventByPoints(tcx, ep, eq, triangle, point);
    } else {
        // This triangle crosses constraint so lets flippin start!
        flipEdgeEvent(tcx, ep, eq, triangle, point);
    }
}

function isEdgeSideOfTriangle(triangle, ep, eq) {
    var index = triangle.edgeIndex(ep, eq);
    if (index !== -1) {
        triangle.markConstrainedEdgeByIndex(index);
        var t = triangle.getNeighbor(index);
        if (t) {
            t.markConstrainedEdgeByPoints(ep, eq);
        }
        return true;
    }
    return false;
}

/**
 * Creates a new front triangle and legalize it
 * @param {!SweepContext} tcx - SweepContext object
 */
function newFrontTriangle(tcx, point, node) {
    var triangle = new Triangle(point, node.point, node.next.point);

    triangle.markNeighbor(node.triangle);
    tcx.addToMap(triangle);

    var new_node = new Node(point);
    new_node.next = node.next;
    new_node.prev = node;
    node.next.prev = new_node;
    node.next = new_node;

    if (!legalize(tcx, triangle)) {
        tcx.mapTriangleToNodes(triangle);
    }

    return new_node;
}

/**
 * Adds a triangle to the advancing front to fill a hole.
 * @param {!SweepContext} tcx - SweepContext object
 * @param node - middle node, that is the bottom of the hole
 */
function fill(tcx, node) {
    var triangle = new Triangle(node.prev.point, node.point, node.next.point);

    // TODO: should copy the constrained_edge value from neighbor triangles
    //       for now constrained_edge values are copied during the legalize
    triangle.markNeighbor(node.prev.triangle);
    triangle.markNeighbor(node.triangle);

    tcx.addToMap(triangle);

    // Update the advancing front
    node.prev.next = node.next;
    node.next.prev = node.prev;


    // If it was legalized the triangle has already been mapped
    if (!legalize(tcx, triangle)) {
        tcx.mapTriangleToNodes(triangle);
    }

    //tcx.removeNode(node);
}

/**
 * Fills holes in the Advancing Front
 * @param {!SweepContext} tcx - SweepContext object
 */
function fillAdvancingFront(tcx, n) {
    // Fill right holes
    var node = n.next;
    while (node.next) {
        // TODO integrate here changes from C++ version
        // (C++ repo revision acf81f1f1764 dated April 7, 2012)
        if (isAngleObtuse(node.point, node.next.point, node.prev.point)) {
            break;
        }
        fill(tcx, node);
        node = node.next;
    }

    // Fill left holes
    node = n.prev;
    while (node.prev) {
        // TODO integrate here changes from C++ version
        // (C++ repo revision acf81f1f1764 dated April 7, 2012)
        if (isAngleObtuse(node.point, node.next.point, node.prev.point)) {
            break;
        }
        fill(tcx, node);
        node = node.prev;
    }

    // Fill right basins
    if (n.next && n.next.next) {
        if (isBasinAngleRight(n)) {
            fillBasin(tcx, n);
        }
    }
}

/**
 * The basin angle is decided against the horizontal line [1,0].
 * @param {Node} node
 * @return {boolean} true if angle < 3*π/4
 */
function isBasinAngleRight(node) {
    var ax = node.point.x - node.next.next.point.x;
    var ay = node.point.y - node.next.next.point.y;
    assert(ay >= 0, "unordered y");
    return (ax >= 0 || Math.abs(ax) < ay);
}

/**
 * Returns true if triangle was legalized
 * @param {!SweepContext} tcx - SweepContext object
 * @return {boolean}
 */
function legalize(tcx, t) {
    // To legalize a triangle we start by finding if any of the three edges
    // violate the Delaunay condition
    for (var i = 0; i < 3; ++i) {
        if (t.delaunay_edge[i]) {
            continue;
        }
        var ot = t.getNeighbor(i);
        if (ot) {
            var p = t.getPoint(i);
            var op = ot.oppositePoint(t, p);
            var oi = ot.index(op);

            // If this is a Constrained Edge or a Delaunay Edge(only during recursive legalization)
            // then we should not try to legalize
            if (ot.constrained_edge[oi] || ot.delaunay_edge[oi]) {
                t.constrained_edge[i] = ot.constrained_edge[oi];
                continue;
            }

            var inside = inCircle(p, t.pointCCW(p), t.pointCW(p), op);
            if (inside) {
                // Lets mark this shared edge as Delaunay
                t.delaunay_edge[i] = true;
                ot.delaunay_edge[oi] = true;

                // Lets rotate shared edge one vertex CW to legalize it
                rotateTrianglePair(t, p, ot, op);

                // We now got one valid Delaunay Edge shared by two triangles
                // This gives us 4 new edges to check for Delaunay

                // Make sure that triangle to node mapping is done only one time for a specific triangle
                var not_legalized = !legalize(tcx, t);
                if (not_legalized) {
                    tcx.mapTriangleToNodes(t);
                }

                not_legalized = !legalize(tcx, ot);
                if (not_legalized) {
                    tcx.mapTriangleToNodes(ot);
                }
                // Reset the Delaunay edges, since they only are valid Delaunay edges
                // until we add a new triangle or point.
                // XXX: need to think about this. Can these edges be tried after we
                //      return to previous recursive level?
                t.delaunay_edge[i] = false;
                ot.delaunay_edge[oi] = false;

                // If triangle have been legalized no need to check the other edges since
                // the recursive legalization will handles those so we can end here.
                return true;
            }
        }
    }
    return false;
}

/**
 * <b>Requirement</b>:<br>
 * 1. a,b and c form a triangle.<br>
 * 2. a and d is know to be on opposite side of bc<br>
 * <pre>
 *                a
 *                +
 *               / \
 *              /   \
 *            b/     \c
 *            +-------+
 *           /    d    \
 *          /           \
 * </pre>
 * <b>Fact</b>: d has to be in area B to have a chance to be inside the circle formed by
 *  a,b and c<br>
 *  d is outside B if orient2d(a,b,d) or orient2d(c,a,d) is CW<br>
 *  This preknowledge gives us a way to optimize the incircle test
 * @param pa - triangle point, opposite d
 * @param pb - triangle point
 * @param pc - triangle point
 * @param pd - point opposite a
 * @return {boolean} true if d is inside circle, false if on circle edge
 */
function inCircle(pa, pb, pc, pd) {
    var adx = pa.x - pd.x;
    var ady = pa.y - pd.y;
    var bdx = pb.x - pd.x;
    var bdy = pb.y - pd.y;

    var adxbdy = adx * bdy;
    var bdxady = bdx * ady;
    var oabd = adxbdy - bdxady;
    if (oabd <= 0) {
        return false;
    }

    var cdx = pc.x - pd.x;
    var cdy = pc.y - pd.y;

    var cdxady = cdx * ady;
    var adxcdy = adx * cdy;
    var ocad = cdxady - adxcdy;
    if (ocad <= 0) {
        return false;
    }

    var bdxcdy = bdx * cdy;
    var cdxbdy = cdx * bdy;

    var alift = adx * adx + ady * ady;
    var blift = bdx * bdx + bdy * bdy;
    var clift = cdx * cdx + cdy * cdy;

    var det = alift * (bdxcdy - cdxbdy) + blift * ocad + clift * oabd;
    return det > 0;
}

/**
 * Rotates a triangle pair one vertex CW
 *<pre>
 *       n2                    n2
 *  P +-----+             P +-----+
 *    | t  /|               |\  t |
 *    |   / |               | \   |
 *  n1|  /  |n3           n1|  \  |n3
 *    | /   |    after CW   |   \ |
 *    |/ oT |               | oT \|
 *    +-----+ oP            +-----+
 *       n4                    n4
 * </pre>
 */
function rotateTrianglePair(t, p, ot, op) {
    var n1, n2, n3, n4;
    n1 = t.neighborCCW(p);
    n2 = t.neighborCW(p);
    n3 = ot.neighborCCW(op);
    n4 = ot.neighborCW(op);

    var ce1, ce2, ce3, ce4;
    ce1 = t.getConstrainedEdgeCCW(p);
    ce2 = t.getConstrainedEdgeCW(p);
    ce3 = ot.getConstrainedEdgeCCW(op);
    ce4 = ot.getConstrainedEdgeCW(op);

    var de1, de2, de3, de4;
    de1 = t.getDelaunayEdgeCCW(p);
    de2 = t.getDelaunayEdgeCW(p);
    de3 = ot.getDelaunayEdgeCCW(op);
    de4 = ot.getDelaunayEdgeCW(op);

    t.legalize(p, op);
    ot.legalize(op, p);

    // Remap delaunay_edge
    ot.setDelaunayEdgeCCW(p, de1);
    t.setDelaunayEdgeCW(p, de2);
    t.setDelaunayEdgeCCW(op, de3);
    ot.setDelaunayEdgeCW(op, de4);

    // Remap constrained_edge
    ot.setConstrainedEdgeCCW(p, ce1);
    t.setConstrainedEdgeCW(p, ce2);
    t.setConstrainedEdgeCCW(op, ce3);
    ot.setConstrainedEdgeCW(op, ce4);

    // Remap neighbors
    // XXX: might optimize the markNeighbor by keeping track of
    //      what side should be assigned to what neighbor after the
    //      rotation. Now mark neighbor does lots of testing to find
    //      the right side.
    t.clearNeighbors();
    ot.clearNeighbors();
    if (n1) {
        ot.markNeighbor(n1);
    }
    if (n2) {
        t.markNeighbor(n2);
    }
    if (n3) {
        t.markNeighbor(n3);
    }
    if (n4) {
        ot.markNeighbor(n4);
    }
    t.markNeighbor(ot);
}

/**
 * Fills a basin that has formed on the Advancing Front to the right
 * of given node.<br>
 * First we decide a left,bottom and right node that forms the
 * boundaries of the basin. Then we do a reqursive fill.
 *
 * @param {!SweepContext} tcx - SweepContext object
 * @param node - starting node, this or next node will be left node
 */
function fillBasin(tcx, node) {
    if (orient2d(node.point, node.next.point, node.next.next.point) === Orientation.CCW) {
        tcx.basin.left_node = node.next.next;
    } else {
        tcx.basin.left_node = node.next;
    }

    // Find the bottom and right node
    tcx.basin.bottom_node = tcx.basin.left_node;
    while (tcx.basin.bottom_node.next && tcx.basin.bottom_node.point.y >= tcx.basin.bottom_node.next.point.y) {
        tcx.basin.bottom_node = tcx.basin.bottom_node.next;
    }
    if (tcx.basin.bottom_node === tcx.basin.left_node) {
        // No valid basin
        return;
    }

    tcx.basin.right_node = tcx.basin.bottom_node;
    while (tcx.basin.right_node.next && tcx.basin.right_node.point.y < tcx.basin.right_node.next.point.y) {
        tcx.basin.right_node = tcx.basin.right_node.next;
    }
    if (tcx.basin.right_node === tcx.basin.bottom_node) {
        // No valid basins
        return;
    }

    tcx.basin.width = tcx.basin.right_node.point.x - tcx.basin.left_node.point.x;
    tcx.basin.left_highest = tcx.basin.left_node.point.y > tcx.basin.right_node.point.y;

    fillBasinReq(tcx, tcx.basin.bottom_node);
}

/**
 * Recursive algorithm to fill a Basin with triangles
 *
 * @param {!SweepContext} tcx - SweepContext object
 * @param node - bottom_node
 */
function fillBasinReq(tcx, node) {
    // if shallow stop filling
    if (isShallow(tcx, node)) {
        return;
    }

    fill(tcx, node);

    var o;
    if (node.prev === tcx.basin.left_node && node.next === tcx.basin.right_node) {
        return;
    } else if (node.prev === tcx.basin.left_node) {
        o = orient2d(node.point, node.next.point, node.next.next.point);
        if (o === Orientation.CW) {
            return;
        }
        node = node.next;
    } else if (node.next === tcx.basin.right_node) {
        o = orient2d(node.point, node.prev.point, node.prev.prev.point);
        if (o === Orientation.CCW) {
            return;
        }
        node = node.prev;
    } else {
        // Continue with the neighbor node with lowest Y value
        if (node.prev.point.y < node.next.point.y) {
            node = node.prev;
        } else {
            node = node.next;
        }
    }

    fillBasinReq(tcx, node);
}

function isShallow(tcx, node) {
    var height;
    if (tcx.basin.left_highest) {
        height = tcx.basin.left_node.point.y - node.point.y;
    } else {
        height = tcx.basin.right_node.point.y - node.point.y;
    }

    // if shallow stop filling
    if (tcx.basin.width > height) {
        return true;
    }
    return false;
}

function fillEdgeEvent(tcx, edge, node) {
    if (tcx.edge_event.right) {
        fillRightAboveEdgeEvent(tcx, edge, node);
    } else {
        fillLeftAboveEdgeEvent(tcx, edge, node);
    }
}

function fillRightAboveEdgeEvent(tcx, edge, node) {
    while (node.next.point.x < edge.p.x) {
        // Check if next node is below the edge
        if (orient2d(edge.q, node.next.point, edge.p) === Orientation.CCW) {
            fillRightBelowEdgeEvent(tcx, edge, node);
        } else {
            node = node.next;
        }
    }
}

function fillRightBelowEdgeEvent(tcx, edge, node) {
    if (node.point.x < edge.p.x) {
        if (orient2d(node.point, node.next.point, node.next.next.point) === Orientation.CCW) {
            // Concave
            fillRightConcaveEdgeEvent(tcx, edge, node);
        } else {
            // Convex
            fillRightConvexEdgeEvent(tcx, edge, node);
            // Retry this one
            fillRightBelowEdgeEvent(tcx, edge, node);
        }
    }
}

function fillRightConcaveEdgeEvent(tcx, edge, node) {
    fill(tcx, node.next);
    if (node.next.point !== edge.p) {
        // Next above or below edge?
        if (orient2d(edge.q, node.next.point, edge.p) === Orientation.CCW) {
            // Below
            if (orient2d(node.point, node.next.point, node.next.next.point) === Orientation.CCW) {
                // Next is concave
                fillRightConcaveEdgeEvent(tcx, edge, node);
            } else {
                // Next is convex
                /* jshint noempty:false */
            }
        }
    }
}

function fillRightConvexEdgeEvent(tcx, edge, node) {
    // Next concave or convex?
    if (orient2d(node.next.point, node.next.next.point, node.next.next.next.point) === Orientation.CCW) {
        // Concave
        fillRightConcaveEdgeEvent(tcx, edge, node.next);
    } else {
        // Convex
        // Next above or below edge?
        if (orient2d(edge.q, node.next.next.point, edge.p) === Orientation.CCW) {
            // Below
            fillRightConvexEdgeEvent(tcx, edge, node.next);
        } else {
            // Above
            /* jshint noempty:false */
        }
    }
}

function fillLeftAboveEdgeEvent(tcx, edge, node) {
    while (node.prev.point.x > edge.p.x) {
        // Check if next node is below the edge
        if (orient2d(edge.q, node.prev.point, edge.p) === Orientation.CW) {
            fillLeftBelowEdgeEvent(tcx, edge, node);
        } else {
            node = node.prev;
        }
    }
}

function fillLeftBelowEdgeEvent(tcx, edge, node) {
    if (node.point.x > edge.p.x) {
        if (orient2d(node.point, node.prev.point, node.prev.prev.point) === Orientation.CW) {
            // Concave
            fillLeftConcaveEdgeEvent(tcx, edge, node);
        } else {
            // Convex
            fillLeftConvexEdgeEvent(tcx, edge, node);
            // Retry this one
            fillLeftBelowEdgeEvent(tcx, edge, node);
        }
    }
}

function fillLeftConvexEdgeEvent(tcx, edge, node) {
    // Next concave or convex?
    if (orient2d(node.prev.point, node.prev.prev.point, node.prev.prev.prev.point) === Orientation.CW) {
        // Concave
        fillLeftConcaveEdgeEvent(tcx, edge, node.prev);
    } else {
        // Convex
        // Next above or below edge?
        if (orient2d(edge.q, node.prev.prev.point, edge.p) === Orientation.CW) {
            // Below
            fillLeftConvexEdgeEvent(tcx, edge, node.prev);
        } else {
            // Above
            /* jshint noempty:false */
        }
    }
}

function fillLeftConcaveEdgeEvent(tcx, edge, node) {
    fill(tcx, node.prev);
    if (node.prev.point !== edge.p) {
        // Next above or below edge?
        if (orient2d(edge.q, node.prev.point, edge.p) === Orientation.CW) {
            // Below
            if (orient2d(node.point, node.prev.point, node.prev.prev.point) === Orientation.CW) {
                // Next is concave
                fillLeftConcaveEdgeEvent(tcx, edge, node);
            } else {
                // Next is convex
                /* jshint noempty:false */
            }
        }
    }
}

function flipEdgeEvent(tcx, ep, eq, t, p) {
    var ot = t.neighborAcross(p);
    assert(ot, "FLIP failed due to missing triangle!");

    var op = ot.oppositePoint(t, p);

    // Additional check from Java version (see issue #88)
    if (t.getConstrainedEdgeAcross(p)) {
        var index = t.index(p);
        throw new PointError("poly2tri Intersecting Constraints",
                [p, op, t.getPoint((index + 1) % 3), t.getPoint((index + 2) % 3)]);
    }

    if (inScanArea(p, t.pointCCW(p), t.pointCW(p), op)) {
        // Lets rotate shared edge one vertex CW
        rotateTrianglePair(t, p, ot, op);
        tcx.mapTriangleToNodes(t);
        tcx.mapTriangleToNodes(ot);

        // XXX: in the original C++ code for the next 2 lines, we are
        // comparing point values (and not pointers). In this JavaScript
        // code, we are comparing point references (pointers). This works
        // because we can't have 2 different points with the same values.
        // But to be really equivalent, we should use "Point.equals" here.
        if (p === eq && op === ep) {
            if (eq === tcx.edge_event.constrained_edge.q && ep === tcx.edge_event.constrained_edge.p) {
                t.markConstrainedEdgeByPoints(ep, eq);
                ot.markConstrainedEdgeByPoints(ep, eq);
                legalize(tcx, t);
                legalize(tcx, ot);
            } else {
                // XXX: I think one of the triangles should be legalized here?
                /* jshint noempty:false */
            }
        } else {
            var o = orient2d(eq, op, ep);
            t = nextFlipTriangle(tcx, o, t, ot, p, op);
            flipEdgeEvent(tcx, ep, eq, t, p);
        }
    } else {
        var newP = nextFlipPoint(ep, eq, ot, op);
        flipScanEdgeEvent(tcx, ep, eq, t, ot, newP);
        edgeEventByPoints(tcx, ep, eq, t, p);
    }
}

/**
 * After a flip we have two triangles and know that only one will still be
 * intersecting the edge. So decide which to contiune with and legalize the other
 *
 * @param {!SweepContext} tcx - SweepContext object
 * @param o - should be the result of an orient2d( eq, op, ep )
 * @param t - triangle 1
 * @param ot - triangle 2
 * @param p - a point shared by both triangles
 * @param op - another point shared by both triangles
 * @return returns the triangle still intersecting the edge
 */
function nextFlipTriangle(tcx, o, t, ot, p, op) {
    var edge_index;
    if (o === Orientation.CCW) {
        // ot is not crossing edge after flip
        edge_index = ot.edgeIndex(p, op);
        ot.delaunay_edge[edge_index] = true;
        legalize(tcx, ot);
        ot.clearDelaunayEdges();
        return t;
    }

    // t is not crossing edge after flip
    edge_index = t.edgeIndex(p, op);

    t.delaunay_edge[edge_index] = true;
    legalize(tcx, t);
    t.clearDelaunayEdges();
    return ot;
}

/**
 * When we need to traverse from one triangle to the next we need
 * the point in current triangle that is the opposite point to the next
 * triangle.
 */
function nextFlipPoint(ep, eq, ot, op) {
    var o2d = orient2d(eq, op, ep);
    if (o2d === Orientation.CW) {
        // Right
        return ot.pointCCW(op);
    } else if (o2d === Orientation.CCW) {
        // Left
        return ot.pointCW(op);
    } else {
        throw new PointError("poly2tri [Unsupported] nextFlipPoint: opposing point on constrained edge!", [eq, op, ep]);
    }
}

/**
 * Scan part of the FlipScan algorithm<br>
 * When a triangle pair isn't flippable we will scan for the next
 * point that is inside the flip triangle scan area. When found
 * we generate a new flipEdgeEvent
 *
 * @param {!SweepContext} tcx - SweepContext object
 * @param ep - last point on the edge we are traversing
 * @param eq - first point on the edge we are traversing
 * @param {!Triangle} flip_triangle - the current triangle sharing the point eq with edge
 * @param t
 * @param p
 */
function flipScanEdgeEvent(tcx, ep, eq, flip_triangle, t, p) {
    var ot = t.neighborAcross(p);
    assert(ot, "FLIP failed due to missing triangle");

    var op = ot.oppositePoint(t, p);

    if (inScanArea(eq, flip_triangle.pointCCW(eq), flip_triangle.pointCW(eq), op)) {
        // flip with new edge op.eq
        flipEdgeEvent(tcx, eq, op, ot, op);
    } else {
        var newP = nextFlipPoint(ep, eq, ot, op);
        flipScanEdgeEvent(tcx, ep, eq, flip_triangle, ot, newP);
    }
}


// ----------------------------------------------------------------------Exports

exports.triangulate = triangulate;

},{"./advancingfront":2,"./assert":3,"./pointerror":5,"./triangle":9,"./utils":10}],8:[function(require,module,exports){
/*
 * Poly2Tri Copyright (c) 2009-2014, Poly2Tri Contributors
 * http://code.google.com/p/poly2tri/
 *
 * poly2tri.js (JavaScript port) (c) 2009-2014, Poly2Tri Contributors
 * https://github.com/r3mi/poly2tri.js
 *
 * All rights reserved.
 *
 * Distributed under the 3-clause BSD License, see LICENSE.txt
 */

/* jshint maxcomplexity:6 */

"use strict";


/*
 * Note
 * ====
 * the structure of this JavaScript version of poly2tri intentionally follows
 * as closely as possible the structure of the reference C++ version, to make it
 * easier to keep the 2 versions in sync.
 */

var PointError = require('./pointerror');
var Point = require('./point');
var Triangle = require('./triangle');
var sweep = require('./sweep');
var AdvancingFront = require('./advancingfront');
var Node = AdvancingFront.Node;


// ------------------------------------------------------------------------utils

/**
 * Initial triangle factor, seed triangle will extend 30% of
 * PointSet width to both left and right.
 * @private
 * @const
 */
var kAlpha = 0.3;


// -------------------------------------------------------------------------Edge
/**
 * Represents a simple polygon's edge
 * @constructor
 * @struct
 * @private
 * @param {Point} p1
 * @param {Point} p2
 * @throw {PointError} if p1 is same as p2
 */
var Edge = function(p1, p2) {
    this.p = p1;
    this.q = p2;

    if (p1.y > p2.y) {
        this.q = p1;
        this.p = p2;
    } else if (p1.y === p2.y) {
        if (p1.x > p2.x) {
            this.q = p1;
            this.p = p2;
        } else if (p1.x === p2.x) {
            throw new PointError('poly2tri Invalid Edge constructor: repeated points!', [p1]);
        }
    }

    if (!this.q._p2t_edge_list) {
        this.q._p2t_edge_list = [];
    }
    this.q._p2t_edge_list.push(this);
};


// ------------------------------------------------------------------------Basin
/**
 * @constructor
 * @struct
 * @private
 */
var Basin = function() {
    /** @type {Node} */
    this.left_node = null;
    /** @type {Node} */
    this.bottom_node = null;
    /** @type {Node} */
    this.right_node = null;
    /** @type {number} */
    this.width = 0.0;
    /** @type {boolean} */
    this.left_highest = false;
};

Basin.prototype.clear = function() {
    this.left_node = null;
    this.bottom_node = null;
    this.right_node = null;
    this.width = 0.0;
    this.left_highest = false;
};

// --------------------------------------------------------------------EdgeEvent
/**
 * @constructor
 * @struct
 * @private
 */
var EdgeEvent = function() {
    /** @type {Edge} */
    this.constrained_edge = null;
    /** @type {boolean} */
    this.right = false;
};

// ----------------------------------------------------SweepContext (public API)
/**
 * SweepContext constructor option
 * @typedef {Object} SweepContextOptions
 * @property {boolean=} cloneArrays - if <code>true</code>, do a shallow copy of the Array parameters
 *                  (contour, holes). Points inside arrays are never copied.
 *                  Default is <code>false</code> : keep a reference to the array arguments,
 *                  who will be modified in place.
 */
/**
 * Constructor for the triangulation context.
 * It accepts a simple polyline (with non repeating points),
 * which defines the constrained edges.
 *
 * @example
 *          var contour = [
 *              new poly2tri.Point(100, 100),
 *              new poly2tri.Point(100, 300),
 *              new poly2tri.Point(300, 300),
 *              new poly2tri.Point(300, 100)
 *          ];
 *          var swctx = new poly2tri.SweepContext(contour, {cloneArrays: true});
 * @example
 *          var contour = [{x:100, y:100}, {x:100, y:300}, {x:300, y:300}, {x:300, y:100}];
 *          var swctx = new poly2tri.SweepContext(contour, {cloneArrays: true});
 * @constructor
 * @public
 * @struct
 * @param {Array.<XY>} contour - array of point objects. The points can be either {@linkcode Point} instances,
 *          or any "Point like" custom class with <code>{x, y}</code> attributes.
 * @param {SweepContextOptions=} options - constructor options
 */
var SweepContext = function(contour, options) {
    options = options || {};
    this.triangles_ = [];
    this.map_ = [];
    this.points_ = (options.cloneArrays ? contour.slice(0) : contour);
    this.edge_list = [];

    // Bounding box of all points. Computed at the start of the triangulation,
    // it is stored in case it is needed by the caller.
    this.pmin_ = this.pmax_ = null;

    /**
     * Advancing front
     * @private
     * @type {AdvancingFront}
     */
    this.front_ = null;

    /**
     * head point used with advancing front
     * @private
     * @type {Point}
     */
    this.head_ = null;

    /**
     * tail point used with advancing front
     * @private
     * @type {Point}
     */
    this.tail_ = null;

    /**
     * @private
     * @type {Node}
     */
    this.af_head_ = null;
    /**
     * @private
     * @type {Node}
     */
    this.af_middle_ = null;
    /**
     * @private
     * @type {Node}
     */
    this.af_tail_ = null;

    this.basin = new Basin();
    this.edge_event = new EdgeEvent();

    this.initEdges(this.points_);
};


/**
 * Add a hole to the constraints
 * @example
 *      var swctx = new poly2tri.SweepContext(contour);
 *      var hole = [
 *          new poly2tri.Point(200, 200),
 *          new poly2tri.Point(200, 250),
 *          new poly2tri.Point(250, 250)
 *      ];
 *      swctx.addHole(hole);
 * @example
 *      var swctx = new poly2tri.SweepContext(contour);
 *      swctx.addHole([{x:200, y:200}, {x:200, y:250}, {x:250, y:250}]);
 * @public
 * @param {Array.<XY>} polyline - array of "Point like" objects with {x,y}
 */
SweepContext.prototype.addHole = function(polyline) {
    this.initEdges(polyline);
    var i, len = polyline.length;
    for (i = 0; i < len; i++) {
        this.points_.push(polyline[i]);
    }
    return this; // for chaining
};

/**
 * For backward compatibility
 * @function
 * @deprecated use {@linkcode SweepContext#addHole} instead
 */
SweepContext.prototype.AddHole = SweepContext.prototype.addHole;


/**
 * Add several holes to the constraints
 * @example
 *      var swctx = new poly2tri.SweepContext(contour);
 *      var holes = [
 *          [ new poly2tri.Point(200, 200), new poly2tri.Point(200, 250), new poly2tri.Point(250, 250) ],
 *          [ new poly2tri.Point(300, 300), new poly2tri.Point(300, 350), new poly2tri.Point(350, 350) ]
 *      ];
 *      swctx.addHoles(holes);
 * @example
 *      var swctx = new poly2tri.SweepContext(contour);
 *      var holes = [
 *          [{x:200, y:200}, {x:200, y:250}, {x:250, y:250}],
 *          [{x:300, y:300}, {x:300, y:350}, {x:350, y:350}]
 *      ];
 *      swctx.addHoles(holes);
 * @public
 * @param {Array.<Array.<XY>>} holes - array of array of "Point like" objects with {x,y}
 */
// Method added in the JavaScript version (was not present in the c++ version)
SweepContext.prototype.addHoles = function(holes) {
    var i, len = holes.length;
    for (i = 0; i < len; i++) {
        this.initEdges(holes[i]);
    }
    this.points_ = this.points_.concat.apply(this.points_, holes);
    return this; // for chaining
};


/**
 * Add a Steiner point to the constraints
 * @example
 *      var swctx = new poly2tri.SweepContext(contour);
 *      var point = new poly2tri.Point(150, 150);
 *      swctx.addPoint(point);
 * @example
 *      var swctx = new poly2tri.SweepContext(contour);
 *      swctx.addPoint({x:150, y:150});
 * @public
 * @param {XY} point - any "Point like" object with {x,y}
 */
SweepContext.prototype.addPoint = function(point) {
    this.points_.push(point);
    return this; // for chaining
};

/**
 * For backward compatibility
 * @function
 * @deprecated use {@linkcode SweepContext#addPoint} instead
 */
SweepContext.prototype.AddPoint = SweepContext.prototype.addPoint;


/**
 * Add several Steiner points to the constraints
 * @example
 *      var swctx = new poly2tri.SweepContext(contour);
 *      var points = [
 *          new poly2tri.Point(150, 150),
 *          new poly2tri.Point(200, 250),
 *          new poly2tri.Point(250, 250)
 *      ];
 *      swctx.addPoints(points);
 * @example
 *      var swctx = new poly2tri.SweepContext(contour);
 *      swctx.addPoints([{x:150, y:150}, {x:200, y:250}, {x:250, y:250}]);
 * @public
 * @param {Array.<XY>} points - array of "Point like" object with {x,y}
 */
// Method added in the JavaScript version (was not present in the c++ version)
SweepContext.prototype.addPoints = function(points) {
    this.points_ = this.points_.concat(points);
    return this; // for chaining
};


/**
 * Triangulate the polygon with holes and Steiner points.
 * Do this AFTER you've added the polyline, holes, and Steiner points
 * @example
 *      var swctx = new poly2tri.SweepContext(contour);
 *      swctx.triangulate();
 *      var triangles = swctx.getTriangles();
 * @public
 */
// Shortcut method for sweep.triangulate(SweepContext).
// Method added in the JavaScript version (was not present in the c++ version)
SweepContext.prototype.triangulate = function() {
    sweep.triangulate(this);
    return this; // for chaining
};


/**
 * Get the bounding box of the provided constraints (contour, holes and
 * Steinter points). Warning : these values are not available if the triangulation
 * has not been done yet.
 * @public
 * @returns {{min:Point,max:Point}} object with 'min' and 'max' Point
 */
// Method added in the JavaScript version (was not present in the c++ version)
SweepContext.prototype.getBoundingBox = function() {
    return {min: this.pmin_, max: this.pmax_};
};

/**
 * Get result of triangulation.
 * The output triangles have vertices which are references
 * to the initial input points (not copies): any custom fields in the
 * initial points can be retrieved in the output triangles.
 * @example
 *      var swctx = new poly2tri.SweepContext(contour);
 *      swctx.triangulate();
 *      var triangles = swctx.getTriangles();
 * @example
 *      var contour = [{x:100, y:100, id:1}, {x:100, y:300, id:2}, {x:300, y:300, id:3}];
 *      var swctx = new poly2tri.SweepContext(contour);
 *      swctx.triangulate();
 *      var triangles = swctx.getTriangles();
 *      typeof triangles[0].getPoint(0).id
 *      // → "number"
 * @public
 * @returns {array<Triangle>}   array of triangles
 */
SweepContext.prototype.getTriangles = function() {
    return this.triangles_;
};

/**
 * For backward compatibility
 * @function
 * @deprecated use {@linkcode SweepContext#getTriangles} instead
 */
SweepContext.prototype.GetTriangles = SweepContext.prototype.getTriangles;


// ---------------------------------------------------SweepContext (private API)

/** @private */
SweepContext.prototype.front = function() {
    return this.front_;
};

/** @private */
SweepContext.prototype.pointCount = function() {
    return this.points_.length;
};

/** @private */
SweepContext.prototype.head = function() {
    return this.head_;
};

/** @private */
SweepContext.prototype.setHead = function(p1) {
    this.head_ = p1;
};

/** @private */
SweepContext.prototype.tail = function() {
    return this.tail_;
};

/** @private */
SweepContext.prototype.setTail = function(p1) {
    this.tail_ = p1;
};

/** @private */
SweepContext.prototype.getMap = function() {
    return this.map_;
};

/** @private */
SweepContext.prototype.initTriangulation = function() {
    var xmax = this.points_[0].x;
    var xmin = this.points_[0].x;
    var ymax = this.points_[0].y;
    var ymin = this.points_[0].y;

    // Calculate bounds
    var i, len = this.points_.length;
    for (i = 1; i < len; i++) {
        var p = this.points_[i];
        /* jshint expr:true */
        (p.x > xmax) && (xmax = p.x);
        (p.x < xmin) && (xmin = p.x);
        (p.y > ymax) && (ymax = p.y);
        (p.y < ymin) && (ymin = p.y);
    }
    this.pmin_ = new Point(xmin, ymin);
    this.pmax_ = new Point(xmax, ymax);

    var dx = kAlpha * (xmax - xmin);
    var dy = kAlpha * (ymax - ymin);
    this.head_ = new Point(xmax + dx, ymin - dy);
    this.tail_ = new Point(xmin - dx, ymin - dy);

    // Sort points along y-axis
    this.points_.sort(Point.compare);
};

/** @private */
SweepContext.prototype.initEdges = function(polyline) {
    var i, len = polyline.length;
    for (i = 0; i < len; ++i) {
        this.edge_list.push(new Edge(polyline[i], polyline[(i + 1) % len]));
    }
};

/** @private */
SweepContext.prototype.getPoint = function(index) {
    return this.points_[index];
};

/** @private */
SweepContext.prototype.addToMap = function(triangle) {
    this.map_.push(triangle);
};

/** @private */
SweepContext.prototype.locateNode = function(point) {
    return this.front_.locateNode(point.x);
};

/** @private */
SweepContext.prototype.createAdvancingFront = function() {
    var head;
    var middle;
    var tail;
    // Initial triangle
    var triangle = new Triangle(this.points_[0], this.tail_, this.head_);

    this.map_.push(triangle);

    head = new Node(triangle.getPoint(1), triangle);
    middle = new Node(triangle.getPoint(0), triangle);
    tail = new Node(triangle.getPoint(2));

    this.front_ = new AdvancingFront(head, tail);

    head.next = middle;
    middle.next = tail;
    middle.prev = head;
    tail.prev = middle;
};

/** @private */
SweepContext.prototype.removeNode = function(node) {
    // do nothing
    /* jshint unused:false */
};

/** @private */
SweepContext.prototype.mapTriangleToNodes = function(t) {
    for (var i = 0; i < 3; ++i) {
        if (!t.getNeighbor(i)) {
            var n = this.front_.locatePoint(t.pointCW(t.getPoint(i)));
            if (n) {
                n.triangle = t;
            }
        }
    }
};

/** @private */
SweepContext.prototype.removeFromMap = function(triangle) {
    var i, map = this.map_, len = map.length;
    for (i = 0; i < len; i++) {
        if (map[i] === triangle) {
            map.splice(i, 1);
            break;
        }
    }
};

/**
 * Do a depth first traversal to collect triangles
 * @private
 * @param {Triangle} triangle start
 */
SweepContext.prototype.meshClean = function(triangle) {
    // New implementation avoids recursive calls and use a loop instead.
    // Cf. issues # 57, 65 and 69.
    var triangles = [triangle], t, i;
    /* jshint boss:true */
    while (t = triangles.pop()) {
        if (!t.isInterior()) {
            t.setInterior(true);
            this.triangles_.push(t);
            for (i = 0; i < 3; i++) {
                if (!t.constrained_edge[i]) {
                    triangles.push(t.getNeighbor(i));
                }
            }
        }
    }
};

// ----------------------------------------------------------------------Exports

module.exports = SweepContext;

},{"./advancingfront":2,"./point":4,"./pointerror":5,"./sweep":7,"./triangle":9}],9:[function(require,module,exports){
/*
 * Poly2Tri Copyright (c) 2009-2014, Poly2Tri Contributors
 * http://code.google.com/p/poly2tri/
 *
 * poly2tri.js (JavaScript port) (c) 2009-2014, Poly2Tri Contributors
 * https://github.com/r3mi/poly2tri.js
 *
 * All rights reserved.
 *
 * Distributed under the 3-clause BSD License, see LICENSE.txt
 */

/* jshint maxcomplexity:10 */

"use strict";


/*
 * Note
 * ====
 * the structure of this JavaScript version of poly2tri intentionally follows
 * as closely as possible the structure of the reference C++ version, to make it
 * easier to keep the 2 versions in sync.
 */

var xy = require("./xy");


// ---------------------------------------------------------------------Triangle
/**
 * Triangle class.<br>
 * Triangle-based data structures are known to have better performance than
 * quad-edge structures.
 * See: J. Shewchuk, "Triangle: Engineering a 2D Quality Mesh Generator and
 * Delaunay Triangulator", "Triangulations in CGAL"
 *
 * @constructor
 * @struct
 * @param {!XY} pa  point object with {x,y}
 * @param {!XY} pb  point object with {x,y}
 * @param {!XY} pc  point object with {x,y}
 */
var Triangle = function(a, b, c) {
    /**
     * Triangle points
     * @private
     * @type {Array.<XY>}
     */
    this.points_ = [a, b, c];

    /**
     * Neighbor list
     * @private
     * @type {Array.<Triangle>}
     */
    this.neighbors_ = [null, null, null];

    /**
     * Has this triangle been marked as an interior triangle?
     * @private
     * @type {boolean}
     */
    this.interior_ = false;

    /**
     * Flags to determine if an edge is a Constrained edge
     * @private
     * @type {Array.<boolean>}
     */
    this.constrained_edge = [false, false, false];

    /**
     * Flags to determine if an edge is a Delauney edge
     * @private
     * @type {Array.<boolean>}
     */
    this.delaunay_edge = [false, false, false];
};

var p2s = xy.toString;
/**
 * For pretty printing ex. <code>"[(5;42)(10;20)(21;30)]"</code>.
 * @public
 * @return {string}
 */
Triangle.prototype.toString = function() {
    return ("[" + p2s(this.points_[0]) + p2s(this.points_[1]) + p2s(this.points_[2]) + "]");
};

/**
 * Get one vertice of the triangle.
 * The output triangles of a triangulation have vertices which are references
 * to the initial input points (not copies): any custom fields in the
 * initial points can be retrieved in the output triangles.
 * @example
 *      var contour = [{x:100, y:100, id:1}, {x:100, y:300, id:2}, {x:300, y:300, id:3}];
 *      var swctx = new poly2tri.SweepContext(contour);
 *      swctx.triangulate();
 *      var triangles = swctx.getTriangles();
 *      typeof triangles[0].getPoint(0).id
 *      // → "number"
 * @param {number} index - vertice index: 0, 1 or 2
 * @public
 * @returns {XY}
 */
Triangle.prototype.getPoint = function(index) {
    return this.points_[index];
};

/**
 * For backward compatibility
 * @function
 * @deprecated use {@linkcode Triangle#getPoint} instead
 */
Triangle.prototype.GetPoint = Triangle.prototype.getPoint;

/**
 * Get all 3 vertices of the triangle as an array
 * @public
 * @return {Array.<XY>}
 */
// Method added in the JavaScript version (was not present in the c++ version)
Triangle.prototype.getPoints = function() {
    return this.points_;
};

/**
 * @private
 * @param {number} index
 * @returns {?Triangle}
 */
Triangle.prototype.getNeighbor = function(index) {
    return this.neighbors_[index];
};

/**
 * Test if this Triangle contains the Point object given as parameter as one of its vertices.
 * Only point references are compared, not values.
 * @public
 * @param {XY} point - point object with {x,y}
 * @return {boolean} <code>True</code> if the Point object is of the Triangle's vertices,
 *         <code>false</code> otherwise.
 */
Triangle.prototype.containsPoint = function(point) {
    var points = this.points_;
    // Here we are comparing point references, not values
    return (point === points[0] || point === points[1] || point === points[2]);
};

/**
 * Test if this Triangle contains the Edge object given as parameter as its
 * bounding edges. Only point references are compared, not values.
 * @private
 * @param {Edge} edge
 * @return {boolean} <code>True</code> if the Edge object is of the Triangle's bounding
 *         edges, <code>false</code> otherwise.
 */
Triangle.prototype.containsEdge = function(edge) {
    return this.containsPoint(edge.p) && this.containsPoint(edge.q);
};

/**
 * Test if this Triangle contains the two Point objects given as parameters among its vertices.
 * Only point references are compared, not values.
 * @param {XY} p1 - point object with {x,y}
 * @param {XY} p2 - point object with {x,y}
 * @return {boolean}
 */
Triangle.prototype.containsPoints = function(p1, p2) {
    return this.containsPoint(p1) && this.containsPoint(p2);
};

/**
 * Has this triangle been marked as an interior triangle?
 * @returns {boolean}
 */
Triangle.prototype.isInterior = function() {
    return this.interior_;
};

/**
 * Mark this triangle as an interior triangle
 * @private
 * @param {boolean} interior
 * @returns {Triangle} this
 */
Triangle.prototype.setInterior = function(interior) {
    this.interior_ = interior;
    return this;
};

/**
 * Update neighbor pointers.
 * @private
 * @param {XY} p1 - point object with {x,y}
 * @param {XY} p2 - point object with {x,y}
 * @param {Triangle} t Triangle object.
 * @throws {Error} if can't find objects
 */
Triangle.prototype.markNeighborPointers = function(p1, p2, t) {
    var points = this.points_;
    // Here we are comparing point references, not values
    if ((p1 === points[2] && p2 === points[1]) || (p1 === points[1] && p2 === points[2])) {
        this.neighbors_[0] = t;
    } else if ((p1 === points[0] && p2 === points[2]) || (p1 === points[2] && p2 === points[0])) {
        this.neighbors_[1] = t;
    } else if ((p1 === points[0] && p2 === points[1]) || (p1 === points[1] && p2 === points[0])) {
        this.neighbors_[2] = t;
    } else {
        throw new Error('poly2tri Invalid Triangle.markNeighborPointers() call');
    }
};

/**
 * Exhaustive search to update neighbor pointers
 * @private
 * @param {!Triangle} t
 */
Triangle.prototype.markNeighbor = function(t) {
    var points = this.points_;
    if (t.containsPoints(points[1], points[2])) {
        this.neighbors_[0] = t;
        t.markNeighborPointers(points[1], points[2], this);
    } else if (t.containsPoints(points[0], points[2])) {
        this.neighbors_[1] = t;
        t.markNeighborPointers(points[0], points[2], this);
    } else if (t.containsPoints(points[0], points[1])) {
        this.neighbors_[2] = t;
        t.markNeighborPointers(points[0], points[1], this);
    }
};


Triangle.prototype.clearNeighbors = function() {
    this.neighbors_[0] = null;
    this.neighbors_[1] = null;
    this.neighbors_[2] = null;
};

Triangle.prototype.clearDelaunayEdges = function() {
    this.delaunay_edge[0] = false;
    this.delaunay_edge[1] = false;
    this.delaunay_edge[2] = false;
};

/**
 * Returns the point clockwise to the given point.
 * @private
 * @param {XY} p - point object with {x,y}
 */
Triangle.prototype.pointCW = function(p) {
    var points = this.points_;
    // Here we are comparing point references, not values
    if (p === points[0]) {
        return points[2];
    } else if (p === points[1]) {
        return points[0];
    } else if (p === points[2]) {
        return points[1];
    } else {
        return null;
    }
};

/**
 * Returns the point counter-clockwise to the given point.
 * @private
 * @param {XY} p - point object with {x,y}
 */
Triangle.prototype.pointCCW = function(p) {
    var points = this.points_;
    // Here we are comparing point references, not values
    if (p === points[0]) {
        return points[1];
    } else if (p === points[1]) {
        return points[2];
    } else if (p === points[2]) {
        return points[0];
    } else {
        return null;
    }
};

/**
 * Returns the neighbor clockwise to given point.
 * @private
 * @param {XY} p - point object with {x,y}
 */
Triangle.prototype.neighborCW = function(p) {
    // Here we are comparing point references, not values
    if (p === this.points_[0]) {
        return this.neighbors_[1];
    } else if (p === this.points_[1]) {
        return this.neighbors_[2];
    } else {
        return this.neighbors_[0];
    }
};

/**
 * Returns the neighbor counter-clockwise to given point.
 * @private
 * @param {XY} p - point object with {x,y}
 */
Triangle.prototype.neighborCCW = function(p) {
    // Here we are comparing point references, not values
    if (p === this.points_[0]) {
        return this.neighbors_[2];
    } else if (p === this.points_[1]) {
        return this.neighbors_[0];
    } else {
        return this.neighbors_[1];
    }
};

Triangle.prototype.getConstrainedEdgeCW = function(p) {
    // Here we are comparing point references, not values
    if (p === this.points_[0]) {
        return this.constrained_edge[1];
    } else if (p === this.points_[1]) {
        return this.constrained_edge[2];
    } else {
        return this.constrained_edge[0];
    }
};

Triangle.prototype.getConstrainedEdgeCCW = function(p) {
    // Here we are comparing point references, not values
    if (p === this.points_[0]) {
        return this.constrained_edge[2];
    } else if (p === this.points_[1]) {
        return this.constrained_edge[0];
    } else {
        return this.constrained_edge[1];
    }
};

// Additional check from Java version (see issue #88)
Triangle.prototype.getConstrainedEdgeAcross = function(p) {
    // Here we are comparing point references, not values
    if (p === this.points_[0]) {
        return this.constrained_edge[0];
    } else if (p === this.points_[1]) {
        return this.constrained_edge[1];
    } else {
        return this.constrained_edge[2];
    }
};

Triangle.prototype.setConstrainedEdgeCW = function(p, ce) {
    // Here we are comparing point references, not values
    if (p === this.points_[0]) {
        this.constrained_edge[1] = ce;
    } else if (p === this.points_[1]) {
        this.constrained_edge[2] = ce;
    } else {
        this.constrained_edge[0] = ce;
    }
};

Triangle.prototype.setConstrainedEdgeCCW = function(p, ce) {
    // Here we are comparing point references, not values
    if (p === this.points_[0]) {
        this.constrained_edge[2] = ce;
    } else if (p === this.points_[1]) {
        this.constrained_edge[0] = ce;
    } else {
        this.constrained_edge[1] = ce;
    }
};

Triangle.prototype.getDelaunayEdgeCW = function(p) {
    // Here we are comparing point references, not values
    if (p === this.points_[0]) {
        return this.delaunay_edge[1];
    } else if (p === this.points_[1]) {
        return this.delaunay_edge[2];
    } else {
        return this.delaunay_edge[0];
    }
};

Triangle.prototype.getDelaunayEdgeCCW = function(p) {
    // Here we are comparing point references, not values
    if (p === this.points_[0]) {
        return this.delaunay_edge[2];
    } else if (p === this.points_[1]) {
        return this.delaunay_edge[0];
    } else {
        return this.delaunay_edge[1];
    }
};

Triangle.prototype.setDelaunayEdgeCW = function(p, e) {
    // Here we are comparing point references, not values
    if (p === this.points_[0]) {
        this.delaunay_edge[1] = e;
    } else if (p === this.points_[1]) {
        this.delaunay_edge[2] = e;
    } else {
        this.delaunay_edge[0] = e;
    }
};

Triangle.prototype.setDelaunayEdgeCCW = function(p, e) {
    // Here we are comparing point references, not values
    if (p === this.points_[0]) {
        this.delaunay_edge[2] = e;
    } else if (p === this.points_[1]) {
        this.delaunay_edge[0] = e;
    } else {
        this.delaunay_edge[1] = e;
    }
};

/**
 * The neighbor across to given point.
 * @private
 * @param {XY} p - point object with {x,y}
 * @returns {Triangle}
 */
Triangle.prototype.neighborAcross = function(p) {
    // Here we are comparing point references, not values
    if (p === this.points_[0]) {
        return this.neighbors_[0];
    } else if (p === this.points_[1]) {
        return this.neighbors_[1];
    } else {
        return this.neighbors_[2];
    }
};

/**
 * @private
 * @param {!Triangle} t Triangle object.
 * @param {XY} p - point object with {x,y}
 */
Triangle.prototype.oppositePoint = function(t, p) {
    var cw = t.pointCW(p);
    return this.pointCW(cw);
};

/**
 * Legalize triangle by rotating clockwise around oPoint
 * @private
 * @param {XY} opoint - point object with {x,y}
 * @param {XY} npoint - point object with {x,y}
 * @throws {Error} if oPoint can not be found
 */
Triangle.prototype.legalize = function(opoint, npoint) {
    var points = this.points_;
    // Here we are comparing point references, not values
    if (opoint === points[0]) {
        points[1] = points[0];
        points[0] = points[2];
        points[2] = npoint;
    } else if (opoint === points[1]) {
        points[2] = points[1];
        points[1] = points[0];
        points[0] = npoint;
    } else if (opoint === points[2]) {
        points[0] = points[2];
        points[2] = points[1];
        points[1] = npoint;
    } else {
        throw new Error('poly2tri Invalid Triangle.legalize() call');
    }
};

/**
 * Returns the index of a point in the triangle.
 * The point *must* be a reference to one of the triangle's vertices.
 * @private
 * @param {XY} p - point object with {x,y}
 * @returns {number} index 0, 1 or 2
 * @throws {Error} if p can not be found
 */
Triangle.prototype.index = function(p) {
    var points = this.points_;
    // Here we are comparing point references, not values
    if (p === points[0]) {
        return 0;
    } else if (p === points[1]) {
        return 1;
    } else if (p === points[2]) {
        return 2;
    } else {
        throw new Error('poly2tri Invalid Triangle.index() call');
    }
};

/**
 * @private
 * @param {XY} p1 - point object with {x,y}
 * @param {XY} p2 - point object with {x,y}
 * @return {number} index 0, 1 or 2, or -1 if errror
 */
Triangle.prototype.edgeIndex = function(p1, p2) {
    var points = this.points_;
    // Here we are comparing point references, not values
    if (p1 === points[0]) {
        if (p2 === points[1]) {
            return 2;
        } else if (p2 === points[2]) {
            return 1;
        }
    } else if (p1 === points[1]) {
        if (p2 === points[2]) {
            return 0;
        } else if (p2 === points[0]) {
            return 2;
        }
    } else if (p1 === points[2]) {
        if (p2 === points[0]) {
            return 1;
        } else if (p2 === points[1]) {
            return 0;
        }
    }
    return -1;
};

/**
 * Mark an edge of this triangle as constrained.
 * @private
 * @param {number} index - edge index
 */
Triangle.prototype.markConstrainedEdgeByIndex = function(index) {
    this.constrained_edge[index] = true;
};
/**
 * Mark an edge of this triangle as constrained.
 * @private
 * @param {Edge} edge instance
 */
Triangle.prototype.markConstrainedEdgeByEdge = function(edge) {
    this.markConstrainedEdgeByPoints(edge.p, edge.q);
};
/**
 * Mark an edge of this triangle as constrained.
 * This method takes two Point instances defining the edge of the triangle.
 * @private
 * @param {XY} p - point object with {x,y}
 * @param {XY} q - point object with {x,y}
 */
Triangle.prototype.markConstrainedEdgeByPoints = function(p, q) {
    var points = this.points_;
    // Here we are comparing point references, not values
    if ((q === points[0] && p === points[1]) || (q === points[1] && p === points[0])) {
        this.constrained_edge[2] = true;
    } else if ((q === points[0] && p === points[2]) || (q === points[2] && p === points[0])) {
        this.constrained_edge[1] = true;
    } else if ((q === points[1] && p === points[2]) || (q === points[2] && p === points[1])) {
        this.constrained_edge[0] = true;
    }
};


// ---------------------------------------------------------Exports (public API)

module.exports = Triangle;

},{"./xy":11}],10:[function(require,module,exports){
/*
 * Poly2Tri Copyright (c) 2009-2014, Poly2Tri Contributors
 * http://code.google.com/p/poly2tri/
 *
 * poly2tri.js (JavaScript port) (c) 2009-2014, Poly2Tri Contributors
 * https://github.com/r3mi/poly2tri.js
 *
 * All rights reserved.
 *
 * Distributed under the 3-clause BSD License, see LICENSE.txt
 */

"use strict";

/**
 * Precision to detect repeated or collinear points
 * @private
 * @const {number}
 * @default
 */
var EPSILON = 1e-12;
exports.EPSILON = EPSILON;

/**
 * @private
 * @enum {number}
 * @readonly
 */
var Orientation = {
    "CW": 1,
    "CCW": -1,
    "COLLINEAR": 0
};
exports.Orientation = Orientation;


/**
 * Formula to calculate signed area<br>
 * Positive if CCW<br>
 * Negative if CW<br>
 * 0 if collinear<br>
 * <pre>
 * A[P1,P2,P3]  =  (x1*y2 - y1*x2) + (x2*y3 - y2*x3) + (x3*y1 - y3*x1)
 *              =  (x1-x3)*(y2-y3) - (y1-y3)*(x2-x3)
 * </pre>
 *
 * @private
 * @param {!XY} pa  point object with {x,y}
 * @param {!XY} pb  point object with {x,y}
 * @param {!XY} pc  point object with {x,y}
 * @return {Orientation}
 */
function orient2d(pa, pb, pc) {
    var detleft = (pa.x - pc.x) * (pb.y - pc.y);
    var detright = (pa.y - pc.y) * (pb.x - pc.x);
    var val = detleft - detright;
    if (val > -(EPSILON) && val < (EPSILON)) {
        return Orientation.COLLINEAR;
    } else if (val > 0) {
        return Orientation.CCW;
    } else {
        return Orientation.CW;
    }
}
exports.orient2d = orient2d;


/**
 *
 * @private
 * @param {!XY} pa  point object with {x,y}
 * @param {!XY} pb  point object with {x,y}
 * @param {!XY} pc  point object with {x,y}
 * @param {!XY} pd  point object with {x,y}
 * @return {boolean}
 */
function inScanArea(pa, pb, pc, pd) {
    var oadb = (pa.x - pb.x) * (pd.y - pb.y) - (pd.x - pb.x) * (pa.y - pb.y);
    if (oadb >= -EPSILON) {
        return false;
    }

    var oadc = (pa.x - pc.x) * (pd.y - pc.y) - (pd.x - pc.x) * (pa.y - pc.y);
    if (oadc <= EPSILON) {
        return false;
    }
    return true;
}
exports.inScanArea = inScanArea;


/**
 * Check if the angle between (pa,pb) and (pa,pc) is obtuse i.e. (angle > π/2 || angle < -π/2)
 *
 * @private
 * @param {!XY} pa  point object with {x,y}
 * @param {!XY} pb  point object with {x,y}
 * @param {!XY} pc  point object with {x,y}
 * @return {boolean} true if angle is obtuse
 */
function isAngleObtuse(pa, pb, pc) {
    var ax = pb.x - pa.x;
    var ay = pb.y - pa.y;
    var bx = pc.x - pa.x;
    var by = pc.y - pa.y;
    return (ax * bx + ay * by) < 0;
}
exports.isAngleObtuse = isAngleObtuse;


},{}],11:[function(require,module,exports){
/*
 * Poly2Tri Copyright (c) 2009-2014, Poly2Tri Contributors
 * http://code.google.com/p/poly2tri/
 *
 * poly2tri.js (JavaScript port) (c) 2009-2014, Poly2Tri Contributors
 * https://github.com/r3mi/poly2tri.js
 *
 * All rights reserved.
 *
 * Distributed under the 3-clause BSD License, see LICENSE.txt
 */

"use strict";

/**
 * The following functions operate on "Point" or any "Point like" object with {x,y},
 * as defined by the {@link XY} type
 * ([duck typing]{@link http://en.wikipedia.org/wiki/Duck_typing}).
 * @module
 * @private
 */

/**
 * poly2tri.js supports using custom point class instead of {@linkcode Point}.
 * Any "Point like" object with <code>{x, y}</code> attributes is supported
 * to initialize the SweepContext polylines and points
 * ([duck typing]{@link http://en.wikipedia.org/wiki/Duck_typing}).
 *
 * poly2tri.js might add extra fields to the point objects when computing the
 * triangulation : they are prefixed with <code>_p2t_</code> to avoid collisions
 * with fields in the custom class.
 *
 * @example
 *      var contour = [{x:100, y:100}, {x:100, y:300}, {x:300, y:300}, {x:300, y:100}];
 *      var swctx = new poly2tri.SweepContext(contour);
 *
 * @typedef {Object} XY
 * @property {number} x - x coordinate
 * @property {number} y - y coordinate
 */


/**
 * Point pretty printing : prints x and y coordinates.
 * @example
 *      xy.toStringBase({x:5, y:42})
 *      // → "(5;42)"
 * @protected
 * @param {!XY} p - point object with {x,y}
 * @returns {string} <code>"(x;y)"</code>
 */
function toStringBase(p) {
    return ("(" + p.x + ";" + p.y + ")");
}

/**
 * Point pretty printing. Delegates to the point's custom "toString()" method if exists,
 * else simply prints x and y coordinates.
 * @example
 *      xy.toString({x:5, y:42})
 *      // → "(5;42)"
 * @example
 *      xy.toString({x:5,y:42,toString:function() {return this.x+":"+this.y;}})
 *      // → "5:42"
 * @param {!XY} p - point object with {x,y}
 * @returns {string} <code>"(x;y)"</code>
 */
function toString(p) {
    // Try a custom toString first, and fallback to own implementation if none
    var s = p.toString();
    return (s === '[object Object]' ? toStringBase(p) : s);
}


/**
 * Compare two points component-wise. Ordered by y axis first, then x axis.
 * @param {!XY} a - point object with {x,y}
 * @param {!XY} b - point object with {x,y}
 * @return {number} <code>&lt; 0</code> if <code>a &lt; b</code>,
 *         <code>&gt; 0</code> if <code>a &gt; b</code>,
 *         <code>0</code> otherwise.
 */
function compare(a, b) {
    if (a.y === b.y) {
        return a.x - b.x;
    } else {
        return a.y - b.y;
    }
}

/**
 * Test two Point objects for equality.
 * @param {!XY} a - point object with {x,y}
 * @param {!XY} b - point object with {x,y}
 * @return {boolean} <code>True</code> if <code>a == b</code>, <code>false</code> otherwise.
 */
function equals(a, b) {
    return a.x === b.x && a.y === b.y;
}


module.exports = {
    toString: toString,
    toStringBase: toStringBase,
    compare: compare,
    equals: equals
};

},{}]},{},[6])(6)
});
